Hydraulic transmission



1,628,603 May 10, 1927. w. FERRIS HYDRAULIC TRANSMISS I 0N .Filed July 9. 1921 5 Sheets-Sheet 1 111 TORNEYS.

May 10, 1927 1,628,603

, w. FEB .25 I

HYDRAULIC TRANSMISSION File July 9. 1921 5 Sheets-Sheet s I l E INVENTOR a i w M, w ".I

ATTORNEYS.

May 1o,1921.- 1,628,603

W. FERRIS HYDRAULIC TRANSMISSION Filed July 9. 1921 5 5 t s t 4 Z- G7 g5 'ZI/O i g LIB- l/ -|NVENT0R 775% ATTORNEVY May 10.1927. 6 ,603

w. FERRIS HYDRAULIC TRANSMISSION Filed JulyQ. 1921 5 s t s t 5 H fizz/6722507" an Fig. '5 is a section v Patented May 10,

" UNITED STA -Es; P

WALTER rnaars, or MILWAUKEE, wrsconsnv, assreizon'ro 'THE cinema COMPANY,

or MILWAUKEE, ,WISCOH'SIN, A CORPORATION or wrsconsm.

HYDRAULIC raaiv'sm'rssron.

i Application filed July 9, 1921. SerialNo. 483,468.

- vThisinvemtion relates to hydraulic transmissions, and more articularly -to pumps and fluid motors of ithe rotary, multiple piston type. j

I It contemplates more especially the provision of a hyraulic system having a motor driven by hydraulic pressure derived from a pump through a closed hydraulic circuit between the pum and motor. )0.

for illustrative purposes, such means are provided to permit a variance in pump dis. placement only, 1 it being understood that similar means may be employedto vary the stroke of .the motor. i Afurther object is the provision of improved-controlling means for the adjustable parts whereby a more-efiicient and less complicated mechanism is produced. Ajstill further objectis .to improve the construction and operation of devices of this character so as to permit'the parts to be to facilitate the-removal of separate com ponent parts or groups ofparts without disturbing or interfering with the other elements of the machine.

vQther more specific objects and advan-- 'tages will appear from the following de: scription of an illustrative embodiment of this invention. v

In the drawings: 4

-Eig. 1 is a partial end. sectional view of,

the hydraulictransmission constructed in accordance with the present invention, the section being taken-substantially alongf'line 1-1 ofFig r Fig: 2 is a sectional view. taken substan. tially alongmthe lines 22 of Figs. 1 and. 3. Fig.3*is a sectional plan view taleii substantially alon the line 33of'Fig.-2'.

Fig; i is a. ragmentarysectional view of the relief jmechanism taken substantially along the broken line of F1g. 5.

on the-line 5-5 of Figs. 3 and 4-; p :2 a F'g. 6 isa section along the line of is a section along the line 7.'Z of One object of-t e present invention is to I provide means whereby the displacement of hub-A A is laterally offset with respect to the C rigidly anchored in an appropriate boss .bottom of the housing. The

'- may be inadeto'coincide the stationary hub A, or (ii Fig. '7 is an end view of Fig. 7; Fig. 8 is a section on-'the* broken line 88ofFig.2; K I Fig; 9 is a section partly on the broken line 9-9 and partly on the broken line Fig. 10 isa section 'alongline 10-'10 of Fig. 9.

The hydraulic transmission shown is-en' closed within a housing which is divided by a partition A into a motor compartment A and. a pump compartment A. The pump end of the housing is closed by a removable plate A? and the motor end' by a movable plate A. The cover A? is fashioned to provide a hub A within which is an antifriction bearing A. fora shaft A drivenby the motor. The motor includes a'polyg onal drumor cage A keyed at its outer end to the shaft A and supported at its inner end by an anti-friction hearing A, carried by a sleeve e2 ztension "-A of a fixed constituting an integral part of artition A. The axis of the sleeve the axis of the hub A and coincident with the axis of the. shaft A assembled and disassembled with ease, and

C formed in a cradle C. The cradle'C is-disposed in upright position and rockably mounted upon a gudgeon or stub shaft formed in the partition A adjacent the drive shaft is journalled-in an anti-friction bearing C provided in: the cradle C and projects throu h the end cover A of the housing, so that t e shaft C and drum A maybe shifted laterally as a-lmit, by swinging the cradle upon :the gudgeon C. .By thisad w, justment the axis of rotation of the drum he axis of h d h f ma later ally to-eit er si e t ereo e' sw 'ngi' In of the cradle is eifectedand controlled ref erably by niechanism to be hereinafier'de-1o5 scribed connected to pins Chappropriately mounted in the upper portion of the cradle.

-:From the foregoing-it he noted that the motor drum, A is mounted for rotation about a fixed axis permanently ofisetfrom.

" a pintle B. The pintle is the axis of the hub A; whereas theopump drum A is mounted for rotation about a laterally adjustable axis whose position is determined by the cradle C. Otherwise however the construction of the pump is substantially identical with that of the motor. Each includes a cylinder barrel B or B disposed within the drum A or 'A' and rotatably mounted upon an end of v V firmly fixed within and concentrically of the hub A so that the axis of rotation of the cylinder barrels are both fixed. Each cylinder barrel contains two parallel series ofcylinder bores 13 or 15 B and B or B A plunger B or B is closely fitted for lengthwise reciprocation in each ho ref Each plungerrprpjects radially from its associated cylinder barrel B or B" and is connected to the encircling drum '4. 8

or A' preferably through mechanism such as shown in detail in Fi ures 8 and 9.

As indicated in these gures a push pin B is loosely engaged within each plunger an retainedin assembled relation therewith by a pin .13 projected loosely therethrough. Each pin B 'bears against a convexseat B provided in the lower end of the plunger, the'arrangement being such as to permit limited play between each push pin and plunger, with binding action from a'slight and plunger.

pins are rigidly connected by 13", disposed normal thereto.

misalinement of a push pm Each pair of parallel push a cross-head Each crossdriver, and since the a view to eliminating any that mlght otherwise occur I head B is guided for lengthwise reciproca-- tion between tangential faces B formed on the drum and a reaction plate'B, removably fixed in appropriate grooves B formed 40 in the drum, an appropriate anti-friction bearing being interposed between each crosshead and reaction plate. The anti-friction \bearing shown comprises two laterally spaced pairs of rollers 13 and 13 disposed above a push pin B of each pair, respectively, and in rollingv contact with the op posed plate. The rollers of each pair are jour 0 cage B and a pinion B, journalled in the central portion of the cage, meshes with racks B* and B formed in the opposed faces of the cross-head and reaction plate,

so that the rollers are maintained in proper mechanism shown for swinging and shown, particularly faces of the cross-head and reaction nalled in the opposite ends of an appropriate.

relation during relative reciprocation be-' of the cradle C will gressively increasing direction of current wardly converging-whosecentral axes an on,

this mechanism includes in Figures 1 and 2 I controlling piston D .0" to exert a tension on the links D by means of the ,spring D which surrounds the 7?) piston rod and reacts against the two check nuts D D by whi'clrthe tension on the springmay be coritrolled so as to set the spring up tight and take out any slack or back lash in the ,links or cross-head. The mechanism for controlling the hydraulic cylinder will-hereafter be described. Suffice it to say that the operation of that cylinder l tends'to rotate the cradle about the gudgeon pin, and since the cradle carries the pump cylinder arrel is mounted on the stationary pintle, a moved ment of the cradle willtend to displace the axis of the pump driver with respect to the axis of the cylinder barrel and thus change the displacement, of the pump. The relation of the parts is such that in the central,position the driver and cylinder barrel are coaxial and rotation ofjtne driving shaft C does not produce any reciprocation of the plungers with respect to the cylinder barrel, and at this point the displacement of the pump jis zero. Any movement of the cradle in either direction from this neutral or dead point willresult in changing the eccentricity 1 pump to have a pro displacement in one depending upon which and thus causing the direction or-the other,

way the cradle moves. A

shown contains two pairs of 10 The pintle B passages E and E. ,At any instant the through these passages may be reversed, but the arrangement is such that when the current moves to the right in the upper passages it moves to the 1" left in the lower, andviceversa. The passages E communicate'with ports E E in the upper side of the pintle adjacent, re spectively, to the central plane of the motor,

and pump cylinder barrels, and the passages E communicate withports E E respectively, adjacent the center plane of the motor and pump barrels on the lower side of the pintle. These ports E E". and E E being in the face of the pintle, communicate with the cylinders B 3" in the pump and motor cylinder barrels by means of the very short passages or cylinder portsEi, each of which is formed of two cylindrical bores downy y, are inclined to the axes, respectively, of each of the two cylinders of each pair, so that the wall between each offtliese "twocylinders is cut away ump 85 toward the bottom, formmg an'oil passage of ample size in each cylinder leading upwardly in V-shape from each of the pintle ports. The divergence of these axes isso determined that'cylindrical cutting tools of the size requisite to form the ports may be introduced along the respective a a port axes, clearing the outer, upper ends of the cylinder bores. The. outer walls ofsaid cylinders opposite the points at which -the T port has cut away the inner walls are chamltlo bered out as at E removing ,a surface area on each side approximately equal to the area of cylinder wall removed on the opposite side by cutting the port. This is for the purpose of preventing the possibility of lateral unbalance-by pressure of the working fluid against the exposed inner surfaces of the plungers which might otherwise cause bindmg and wear of the outer surfaces of the cylinder bores. F is a sprocket on the ump shaft C It drives a sprocket chain which chain in turn drives a sprocket F. This sprocket is 'mounted on a pump shaft F This pump :shaft drives an ordinary conventional type of gear pump comprising two gears;'F F

These pump gears are mounted in a casing .F,- into which oil isdrawn through anintake port F into and through the intake -passage F and discharged through a discharge passage F into-the. ressure line F. F is a springrseated, ad3ustable-pressure, relief valve, -so arranged that the excess oil pumped by the gear. pump, and notrequired to supply the pressure line, will pass out through theunseated pressure relief'valve, to again enter the intake passage F and be again cir culated through the pump.

branches: G,'leading back to the system to 40 supply make-up for any oil. which may have leaked out, and G leading to the strokeshifting hydraulic cylinder D. Thepipe Gr terminates in an elbow G 'which' is screwed into the side wall of thehollow valve stem the piston rod being cut away for a short distance, forming a slot G, so'that the hollow valve stern-may reciprocate independentvalve reduced or necked down at its center and mounted on the end of the hollow valve stem 1G and fitting closely within a slightly enlarged bore G within the piston and pis- 'ton rod. (3': is a radial port in the valve through which oil under pressure, from the interior of the .hollowvalve stem, may pass f out into the annular space Gr surrounding i' the central portion of the valve. Within the piston are passages G G one of them leading from the inner side of the piston to the outer edges of the valve, the other from the outer side of the piston to the inneredge of the valve. In the position shown in Fig. 3, both of these passages are closed by the outer and inner lands of the valve, respec- Gr located within the hollow piston rod D ly of the piston. G is a piston distributing 50' tively. If the valve as shown in Fig. 3 is moved upwardly, the passage G will be brought into communication with the annularpressure space G and oil will pass through this passage into the inner end of the cylinder and tend to force the piston to follow the valve until the source of pressure is cut off.- At the same time the passage'Gr will be brought into communication with the hollow part of the piston rod beyond the valve and the oil or liquid contained within the opposed end of the cylinder will pass out into the space between the hollow valve stem and the piston rod, thence overflowing through. the slot G into the housing. In the event of movement of the valve in the opposite direction, the opposite operation will take place, because in this case the-passage G will be opened to the space between the valve stem and piston rod while the passage 1 will conduct oil under'pressure to force the piston in the o posite direction to follow up the, valve until theports are brought back into the neutral position.

This valve stem is actuated by a lever H pivoted towards its center on the valve stem. H is a linkpivoted atone end on one end of the lever H and at the other end on the hand lever H working against a quadrant H and controlled by a handle H. If the opposed end of the lever H does not move, then manipulation of the handle II will operate the valve. During ,all normal operations ofthe machine under hand control the fulcrum end of the lever H removed from the hand control does not'move' so long as the operator by hand control does not so manipurg The pressure line- F divides into two.

late the machine as to set up abnormal pressures-that is,'pressures'of the working fluid in the machine exceeding a predetermined value. However, in order to protect the apparatus, I provide apressure overload gear, which is calculated, when the operator does so manipulate the device. as to generate in the machine pressures above the predetermined limit, to come into operation and automatically so control the machine as to prevent the pressure rising above a certain predetermined point. In general terms, this device commences operation in time to limit the increase in pressure of the working fluid within certain predetermined limits.

K is apiston slidable in a cylinder K, It carries a piston rod K and this piston rod carries a pin K slidable in the slot K in the lever H. It is this pin K which is normally the fulcrum tor the lever H. K is a spring surrounding the piston rod K confined between the floatin washer K slidable on the piston rod, limited in its downward movement by the shoulder K, and the yoke K adjustable by means of the nut K on the piston rod and slidable within a guide tube K. The movement of the washer K in a direction toward the cylinder is limited the adjustable screw stop by the stop K and the movement of the yoke K in the opposite direction is limited by K The piston rod K is free to slide through both the washer K and yoke K The initial tension of sprin K, corresponding to the predetermine pressure at which piston K is to be set to operate, is determined by the position of the nut K and screw stop K. The nut K is square or polygonal and slid ably mounted in asquare or polygonal interior ot the yoke K Adjustment is made by disconnecting the fulcrum pin K and withdrawing lever H from the slot insthe piston rod K whereupon the piston rod may be rotated and the threaded end in engagement with the nut K will operate to pull the yoke K farther toward the cylinder and further compress the spring. When proper spring tension is reached, the screw stop K is loosened by means of lock screw communicated through valve G causing a corresponding movementin position by the lock screw K.

in ,such direction as K run in until it again abuts against the outer face of yoke K and is again locked When properlyadjusted in any position the spring and associated apparatus rigidly hold the piston Kin central position without any back lash whatever. Any movement of the piston in either direction must be accompanied by a further compression of spring, which can only result from a further rise in pressure. During such motion of the overload piston K the pin H acts as fulcrum for the lever H and motion of the piston K is the lever H to the of the stroke-changing piston D in the manner already described covering the operation of this piston-by hand-control mechanism, so as to vary the pump displacement to limit the increase of pressure from no matter what cause 'said pressure may .originate.

The piston K separates the bore of the overload cylinder K into two pressure spaces, K and K. K is connected through duct K and tube K with a conduit K formed in web A and communicating with passage E. Space K is connected through duct K and tube K with a conduit K with passages E pump shaft is displaced to the right of the axis of pin-tie B, and with the pump shaft I and driver running counter-clockwise, as indicated by the arrow, the pump plungers will be discharging into the upper passages E, which will therefore be high pressure passages so long as the pump is receiving power through. the pump shaft and using said .power to generate pressure in the working I fluid, thereby driving the motor end. Under the workin fluid discharged passages E ton Fig, 2, and enters .these conditions, by the pump flows th r'o'ug ward the left, as shown H as a fulcrum,

As shown in Fig. 1, the

the upper ports and cylinders of the motor, causing the motor to rotate in the direction of the arrow shown on shaft A at the lefthand end of Fig. 3. With the parts in this position, if the motor encounters 'an excessive resistance to its rotation, causing the pressure to rise unduly in the upper passages E, this pressure will be communicated through conduit K tube K duct K to pressure s ace K in the overload cylinder. When sai rising pressure has passed a pre determined limit for which spring K is adjusted, the piston K the center line, moving lever H around pin and thus moving the control valve G toward the center line. This will cause the hydraulic piston D andassociated' parts to move toward the center line and thereby reduce the eccentricity and consequently the displacement of the pump so far as may be necessary to reduce the pump delivery and check the rise of working pressure. If necessary, this reduction in pump eccentricity and displacement will continue until the displacement is zero and there is wno more fluid pumped.

An excessive rise in fluid pressurein the working circuit may, however, originate from the motor end instead of from the efiect,'or when it is driving some machine will move away from I fly-wheel or inertia such as an automobile, which may at times be running down a grade, causing the normal resistance to the motor to entirely disappear and be replaced by conditions which cause the motor to become the driver and convert it into a pump. Under such conditions, with the mechanism in the position just described, the working pressure in passages E (normally caused by the pump) will be converted into a return or exhaust pressure, while the passages E will become high pressure passages receiving the working fluid discharged by the motor acting as a pump. Should the driving eifort delivered to the motor acting as a pump in turn become excessive, the pressure in passages E? will rise beyond a predetermined limit and be commumcated through conduit K tube K duct K to pressure space K thereby mov ing the overload piston K toward the center line, as shown in Fig. 3, and increasing the eccentricity and displacement of the pump beyond the eccentricity shown in Fig. 1. This increase results from moving the center line of pumpshaft and driver away. from the axis of the pintle, instead of moving them toward the axis of. the pintle, which resulted when the rise in pressure origihead is the left of the axis of rotationof the cylinder barrel, then, without any change in direction of rotation of the 15, E E and will communicate through the conduit K tube K and duct K with the pressure chamber K Should the working pressure under these circumstances rise above a predetermined point at which spring K is set tooperate, the piston K will be moved toward the center line of the machine, as shown on Fig. 3, thus operating to reduce the stroke of the pump, thus operating the piston valve G to cause the hydraulic control to positively and progressively reduce the stroke of the pump until the rise of working pressure is checked. Thus it will be seen that upon whichever side of the center of the machine the axis of the pump shaft may be operating at any moment, the excessive working pressure generated by'the pump, above the pressure to which spring K is adjusted,- will result reducing the stroke and displacement of the pump until said rise of workin pressure is checked.

With the axis the pump shaft to left of center line of the machine as shown on Fig. 1, and with normal high pressure genrated by the pump in passage E? as just described,'should circumstances arise which cause the motor to become the driver and act asa pump, the pressure conditions in passages E and Exwould again be interchanged asin the case previously. described, the pressure ports E becoming low pressure or return ports "and the working pressure caused by .the motor acting asa pump would rise- "in passages E. This working pressure then communicates with the pressure chamber K through conduit K tube :K, duct K and should this pressure increase above the limit in pressure to which'K. is adjusted, piston Kflwill be moved away from the cencarrying with it the valveGr by means-o the lever H and associated parts, as previously 1,..described, and thus causing the hydraulic piston D to move thecenter of the pump ,sh'aft a'nd driver further away fromthe .xi 's ofv the cylinder rbarrel, thus increasing tli''displacement of'thep p.

=11:- thus ap ter line of the machine, as shown in Fi '3,

pf'ars that for a given direction right-handed or left-handed rotation of the.

motor, any conditions whatever which result in a rise'ot' pressure in any part of the working circuit above a predetermined maximum 'will result in decreasing the dis- .70 placement of the pump, if the pumpis driving, or of increasing the displacement of the pump if the motor is driving. In general, the pump and the motor are identical and interchangeable mechanisms, and the one which at the moment is acting as a genera-tor of pressure in the liquid is, strictly speaking, the pump, and the one in which theliquid pressure is re-converted into mechanical power is, strictly speaking, the 80 motor. Using these designations, the general statement applies that the overload device just described always responds to excessive pressures by decreasing the ratio of displacement of pump to motor. When only one of the two units is provided with stroke changing mechanism, it necessarily follows that when thatunit isacting as a pump the overload apparatus acts to reduce its displacement in response to excessive pressure, and when the constant displacement unit is acting as a pump the overload mechanism acts to, increase the displacement of the variable displacement unit in order to reduce the ratio stated. V

In a sense it may be said that this apparatus is adapted to operateinterchangeably as a driving unit or as a brake, because if we are driving an inertia load and the load tends to move faster than the motor at any one time then the whole apparatus, instead of accelerating the load, .tends to decelerate-that is, act as a brakeand whe nitis' acting as a brake then the pressure will build up in the system and result in an in- 1 crease of the ratio of pump displacement with respect to motor displacement if the pressure in the system exceeds a predetermined safe point; otherwise, when'act-- ing as a motor or driving apparatus, increase in pressure beyond a predetermined point will result in decreasing the pump displacement with respect to the motor dis placement. I L is a relief valve housing mounted on the transmission housing. L ,"L are pas s ges in the web A in line with the pas-' sages K K and communicating respectively with the passages E, E -These pag- 4 sages L L communicate by means of pdrts 0 L,.L with a cylinder L, in which is mounted forreeiprocation a three piston heads, L and Li, arranged so that the opposed surfaces on L and L and on L and L arein hydraulic balance'1 independent of any pressure variations in the passages L L ,,and the piston'valve can stand at rest until moved by some eiterior q'j force; sothat in the position 1, as-slfown,

with the relief valve closed, thepassages piston valve having i i I and L? and their associated and connecting passageways are separated by the piston head L When the piston is thrown into theposition 2, as shown in dotted lines, by

means which I shall subsequently discuss, the passages L and L are then inconnection through the cylinder L between the piston heads L and L thusshort-circuiting the system and permitting the high pressure pump from causing undesired movement'of the motor.

Thisoperation of the piston valve may be obtained either automatically or by hand machine so sud control. The hand control .com rises a lever L on a shaft L This sha carries a sleeve L forming part of a bell crank comprising a spring lever L and slotted control lever-L the spring lever having anchored thereon a coil spring L anchored on its other end on 'a pin L, the slotted control lever engaging a pin L in a yoke'L on the endof the valve stem L, the position of the spring lever being such that the spring tension holds the valve firmly either in position l or position 2.

The automatic valve control means comprises two passages M, M communicating respectively with the passages L, L. In each one of these passages is mounted for reciprocation a plunger M held in the position shown in Fig. 4 by a spring M thus closing the passages M and M Each of these passages communicates with a vertical duc't M which, in turn, communicates with a transverse duct M discharging into the.

cylinder L above the piston head L there being a boss M on the end of the head to leave a chamber into which liquid nia'yfpass to exert a pressure on the upper end of the piston valve. If the pressure either in the conduits L or L exceeds a certain predetermined limit, the plunger will be thrust back, opening the passage and permitting discharge of liquid through the passages M and M into the cylinder 'to throw the. valve down against the spring pressure and short- 1 circuit the'system, as abovelzfguggested. This is an instantaneous operating of the pressure relief mechanism and it is provided because, .under some conditions of operation, the operator might conceivably overload his only that the pressure control mechanism above discussed, which works to limit pressures by varying displacement,

would not have time to operate. When that is the case, this automatic-pressure relief -goes into instantaneous operation and the valve is locked in thereliefposition, thus compellingthe operator to noticertgit he is overloading the machine and comp'e ng him to "go around and throw the valve back into seated check valves, 0?, which valves are located in the passages 0 O these passages being in open communication with the cylinder L aboveand below the cylinder headL, respectively, when that head is in the central normal position as shown at I in Fig. 5. Whichever .duct, L or L is the high pressure duct, the ball check valve from that duct will,'of course, be lockedby the pressure, but the pressureof the leakage re.- turn pump will be able to unseatthe other check valve enough to ermit the inflow of sufiicient make-up liqui to keep thesystem filledwiththe working fluid.

In Fig. 2 I have shown a clearance between the inner end of the cylinderbarrel and the shoulder. Under many conditions this clearance would not .be present, because under manufacturing conditions the parts would be so sized that the axial pressure exerted by the closing capat the end of the'housing would tend merely to bring the cylinder barrel up against the shoulder and the lateral or axial adjusting means would thenmerely be sufiicient to compensate for the inaccuracies in manufacture.

It will be observed that because thepintle upon which the cylinderbarrel is mounted for rotation is tapered there is a componentresultant from the radial thrust of the plungers tending .to axially displace the cylinder barrel, and the association-or relation between the driving head and the plunger'cross-heads, or between "the driving head and the cylinder barrel, is provided to overcome this axial displacement comonent. Thesh0ulder, 0f course, has no'working function when running because the tapered pintle carries the tapered cylinder barrel and the shoulder is merely thereto give'a definite dimension, the actual diameters of the two parts being such. that when the cylinder barrel is brought up to the shoulder and heldthere by the positioning glevice, as for instance-the-driving head, the oil film between the pi ntle-and'cylinder barrel will be of the proper thickness. movement of'the' cylinder barrel is pref erably resisted by edged contact of the plates or cross-head B with one of the-faces of the drum ,Afithough for some conditions this resistance" might -be provided by engage- Theoutward ment with the hubfof the cylinder barrel against the surface of the drum A adjacent the hub where it engages the shaft A or (3*.

I claim:

1. In a hydraulic machine, a reaction supporting plate mounted for lateral wit 4 drawal across the line of working reaction.

2. In a hydraulic machine, a plurality of radially disposed working members and .a

plurality of reaction plates associated with them and mounted for lateral withdrawal in a plane perpendicular to the axial line of the working members. v

- In a hydraulic machine a pluralityof l5 radially disposed working members and-a plurality, of reaction plates associated with them and mounted for lateral withdrawal in a plane perpendicular to the axial line of the ,wdrking members,-the working members being mounted for radial withdrawal when the reaction plate has, been laterally Withdrawn.

4. In a hydraulic -machine,'a pluralityof radially disposed push pins, cross-heads as- ?5 sociated with them, reaction plates parallel with the cross-heads and mounted: for removal along a line parallel with the crosshead. I

5. In a hydraulic machine, aplurality of radially dis osed push pins, cross-heads associated wit h them, reaction platesparallel with the cross-heads and mounted for removal along lines parallel with' the cross heads and anti-frict on bearings between the cross-heads and the reaction plates.

6. In a hydraulic machine, a plurality of radially dis osed push pins, cross-heads associated wit them, reaction plates parallel with the cross-heads and mounted for re- 0 moval along lines parallel with the crossheads and sliding bearing supports for the crosseads in opposition ,to "the reaction plates. 7

' 7 Ina hydraulic machine, a plurality of 5 radially dis osed push pins, cross-heads as-.

. sociated witi them, reaction plates parallel with the cross-heads and mounted for removal along lines parallel with the crossheads, anti-friction bearings between the cross-heads and the reaction plates and sliding bearing supports for the cross-heads in opposition to the reaction plates. EigSl Ina hydraulic machine, across-head iind a reaction plate, an anti-friction bear- 5; ing between them, a gear associated with suchbearing out'of line with the. bearm fl merliber, and teeth. in the opposed faces 0 the 'cross-head and reaction member'in mesh with said .gear. v 9 9; Ina-hydraulic machine, a cross-head ane-is reaction" piate, 'a n anti-friction bean between them, agearassociated with 'c flbearing utfof line with the bearing ziiember, eeth inthe opposed faces of 5 the cross eadand reaction member in mesh with said gear, said teeth extending clear to the end of cross-head and reaction member a on opposed ends. i

10. In a hydraulic machine, a cross-head and a reaction plate, an anti-friction bearing between them, a gear associated with such bearing out of-line with the bearing member and teeth in theopposed faces of the cross-head and reaction member in mesh with said gear, said teeth extending clear to the end of cross-head and reaction member on opposed ends whereby lateral separation of the cross-head and reaction member causes the gear to roll from between said members. '11. Ina hydraulic machine, two parallel rows of working members, a single cross head associated with each pair of working members, a reaction plate in line with said cross-head, and rolling bearings interposed between the reaction plate and the crosshead, the bearings being divided into two groups one in line with each working member.

12. In a'hydraulic' machine, two parallel rows of working members, a single crosshead associated with each pair of working members, a reaction plate in line with said cross-head, rolling bearings interposed between the reaction plate and the cross-head,

the bearings being divided into two groups one in line with each working member, and

a cage inclosing said bearing members and holdin them in position.

13. n a hydraulic machine, two parallel rows of working members, a single crosshead associated with each pair of working members, a reaction plate in line with said cross-head, rolling bearings interposed between the reaction plate and the cross-head, ms the bearings being divided into 'two groups I one in line with each working member, a cage inclosing said bearing members and holding them in position, and means asso ciated with said cage and engaging the no cross-head and reaction plate b'etweenjthe rows of working members for positioning Y the cage.

14. In a hydraulic machine, two parallel rows of working members, .a single crosshead associated witheac'h pair of working members, a reaction plate in line with said cross-head, rolling bearings interposed between the reaction plate and the cross-head, the bearings being divided into two groups 12 one in line with each working member, a cage inclosing said bearing members and 'ho dingth em in; position, and means associated with said cage andengaglng thecross head and reaction plate between the rows of working members for. positioning' the cage, said means comprising a gear and rack teeth on cross-head andreaction member in mesh with said gear, v

15. Ina hydraulic machine, two parallel ciated with said cage and engaging the crosshead and reaction plate between the rows of working members for positioning the-cage, said means comprising a gear and rack teeth on cross-head and reaction member in mesh with said gear. the reaction member being mounted for lateral withdrawal.

16. In a hydraulic machine, two parallel rows of working members, a single crosshead associated with each pair of working members, a reaction plate in line with said cross-head, rolling bearings interposed between the reaction plate and the cross-head, the bearings being divided into two groups one in line with each working member, a cage inclosing said bearing members and holding them in position, and means associated with said cage and engaging the cross-head and reaction plate between the rows of workingmembers for positioning the cage, said means comprising a gear and rack teeth on cross-head and reaction member vin mesh with said gear, the reaction member being mounted for lateral withdrawal, the working member and crossfhead being mounted for withdrawal at right angles to the reaction member,

17. In a hydraulic machine, a polygonal driving head, a cylinder barrel associated therewith, a cylinder opposite each face of the polygon, a plunger in each cylinder, a hole .in each polygon face through which the plunger may be introduced and withdrawn, a cross-head for each plunger guided on'the polygonal face, and a removable reaction 'plate overlying each polygon face and adapted to position. a

18, Ina hydraulic machine. a polygonal driving head, a cylinder barrel associated therewith, a cylinder opposite each face of the-polygon, a plunger in each-cylinder, a hole in each polyg plunger may be introduced an a cross-head for each plunger guided on the polygonal face, and a" removable reaction .plate overlying each polygon face and the reaction plate beinglaterally removable perpendicular to the line of plnngerithrust. r

19.;In-a hydraulic machine, a polygonal driving head, a cylinder barrel associated t l'ie'r ewith, a cylinder opposite-each face of I [thepolygon,

hole in each polygon face through which a plunger in each cylinder. a

hold the cross-head in working on face throu h-which the withdrawn,

p y ona face,

the plunger may be introduced and withdrawn, a cross-head for. eachplunger guided on the polygonal face, and a removable re-. action plate overlying each polygon face and adapted to hold the cross-head in working position, the reaction plate being laterally removable perpendicular to the line of force, the cross-head. and plunger being radially withdrawab'le after the reaction plate has been withdrawn. J y

20. In a hydraulic. machine, a polygonal driving head, a cylinder barrel associated therewith, a cylinder opposite each face of the polygon, a plunger in each cylinder, an opening in each polygon face through which the plunger may be introduced and withdrawn, a cross-head for each plunger guided on the polygonal face, a removable react-ion plate overlying each polygon face and adapted to hold the cross-head in working position, and a rolling bearing between the cross-head and the reaction plate.

21. In a hydraulic machine, a polygonal driving head, a cylinder barrel associated the polygon, a plunger in each cylinder, a hole in each polygon face through which the plunger may be introduced and withdrawn, a cross-head for each plunger guided on the polygonal face, a removable react-ion plate overlying each polygon face and adapted to hold the cross-head in working position, a rolling bearing between the cross-head and the reaction plate, and means for locating the bearing-in working position between them. i

' 22. In a hydraulic machine, a polygonal driving head, a c linder barrel associated therewith, a cylin er opposite each face of the polygon, a plunger in each cylinder, a' hole in'each polygon face through which the plunger. may be introduced and withdrawn, a cross-head for each plunger guided on the polygonal face, a removable reaction plate overlying each polygon face and adapted to hold the cross-head in working arolling bearing between thecrosshead and the reaction plate,

locating the bearing in working position be;

tween them, said means comprising a pinion,

'the plate and cross-head being toothed to engage the pinion. v i

' 23. In a hydraulic machine, a polygonal driving head, a c linden barrel associated therewith, a cylin er opposite each face of the polygon, a plunger in each cylinder, a

hole in each polygon face through which the plunger may be introduced and withdrawn, a cross-head. for each plunger guided on the a removable reaction plate overlying each polygon face and adapted to hold the cross-head in working position, a rolling bearing between the cross-head and .the reaction plate, and means for locating the -bearing in working position between e5 ml Ill " each cylinder, eacliifac masses them, said means comprising a pinion, the

plate and cross-head "being toothed to efian'd'overlying the aperture therein for pregage'the-pinion, the gear teeth extending to opposite-ends of cross-head and reaction. B -plate to permit the lateral withdrawal ofl the plate and cro:s-head from'register witheach other.

24. In-a hydraulic machine the. combina tion of two coacting members rotatable about substantially parallel axes, hydraulic connections for one of said members, a shaft, connected with the other of said members,

and a rockable support for one of said mem- 'bers movable to shift the axis of rotation of said member relative to that of the other member to vary the fluid displacement of the machine. i

.25. In a hydraulic machine. the combina tion of two coaeting members rotatable about substantially parallel axes, hydraulic connections for one of-said members,ia.shaft connected with the other of said members, a rockable support for said last mentioned member movable to shift the axis of-rotation thereof relative to that. of the other. member to vary to fluid displacement of the machine. g

26. In a hydraulic'machine' the combination of two coacting members rotatable about substantially parallel axes, hydraulic connections for one of said members,af shaft connected with the other of, saidrmel'nbers,"

an adjustable support for said last ;-.men-- tioned member, and hydraulically actuated means for adjusting said supportto var-yj the fluid displacement of the machined 27. In a.hydraulic machine the coinbina-' tion of twocoacting 'Iiie'mbers' rotatable about substantially parallel axes, hydraulic connections for one ofsa'id members ,'a shaft connected with the other of said .membera: an adjustable support for said lastgnanied; member, an auxiliary-fluid pressure sc rce, and means actuated said. sour .0 1?" adjusting said supportil .4 .4 7 28. In ahydraul c machine. a-hollo lygonaldriving. head, linderibarre rrounded thereby, a '1 lit'y of-Tcylindersradially disposed-in t rrel, a plunger in E ie-p'olygon being apertured for the-{insert and withdrawal thereof, and removabl f'm'eansassociated, with each polygon face and overlyingthe aperture therein for preventing'outward movement of the Rlunger-with respect. to-the polygon. a

lygonal driving head, a .jcylinder bar-rel sur-- rounded thereby, 'a .-plurality of cylind"ers-- radially disposedin thefbarr'elsa plungertin each cylinder, each face ppm-{polygon aperturedfor the" insert fd withdrztyval thereof, a cross-heads atedigwitliie'a plunger and in working -"ei1ga'gement w t the outer face of each polygon,.and'remova-f.

blem'eans associated with each'polygon face venting outward movement of the plunger with respect to the polygon.

30.11! a hydraulic machine, a hollow polygonal driving head, acylinder barrel surroundedthereby, a plurality of cylinders radially disposed in the barrel, a plunger in eachcylinder, each face of the polygon being apertured for the insertion and withdrawal thereof, and removable means associated with each ,polygon face and overlying the aperture therein for preventing outward. movement of the plunger with respect to the polygon, said means comprising a laterally removable reaction plate' 31. In a hydraulic machine, a hollow polygonal driving head, a cylinder barrel surrounded thereby, a' plurality of cylinders radially disposed in the barrel, a plunger in each cylinder. each face of the polygon in'g 'apertured for the insertion and withdrawal thereof, a cross-head associated with each plunger and in working engagement with the outer face of eachpolygon, and removable means associated with each polygon face and overlying the aperture therein for preventing outward movement of the plunger with respect to the polygon, said means comprising a laterally removable reaction plate.

32. In a hydraulic machine, a hollow polygonal drivinghead, a cylinder-barrel surrounded thereby, a-plurality of cylinders radially disposed in the barrel, a plunger in each cylinder, each face of the polygon being a ertured for the insertion and withdrawal thereof, removable means associated with each polygon face and overlying the aperture therein for preventing outward movement; 'of;the plunger with respect to the polygon, said means comprising a laterally removable reaction plate, and slotted flanges associated withthe polygon in which the removable-plate is held. I

33: Ina hydraulic machine. a hollow polyg onal drivin head, a cylinder barrel surrounded there y, aplurality of cylinders radially disposed in the barrel. a plunger in each cylinder. each face of the'polygon being; apertured zfoijthe insertion and with-' drawal thereof,-a cross-head associated with each-plunger and *in' working engagement with the outer face of each polygon, removable meahs' associated with each polygon face j and overlying the aperture therein for pre- 29. In a hydraulic. machine, a hollow po-- venting 'outwardimovementaof the plunger with respect to the polygon, said means comprising' aflaterallyremovable reaction plate, and s'lottegflanges associated with the polyon :w

iii-hydraulic machine, two opposed flanges, radial working members iiicatedi jbetween said flanges, and 'a rigid reaction" member preventing radial movement ich -thfegremovable plate is held.-

of each of said Working members compris ing a plate supported by said flanges.

. 35. In a hydraulic machine, two opposed parallel flanges, radial working members loeated between said flanges, and a rigid react1on member preventing radial movement of each of. said working members comprising a being laterally movable within said slots to plate supported by said flanges, the flanges being slotted tov engage the plate.

36. In a hydraulic machine. two opposed parallel flanges, radial working members located between sai'dflanges, and a rigid reaction inemberpreve'nting radial movement of each of said working members comprising a plate supported bysaid flanges, the. flanges being slotted to engage the plate. the plate uncover the working members and permit their radial withdrawal. for disassembling.

37. In a hydraulic machine, two opposed parallel flanges, radial working members located between said flanges, a rigid reaction member preventing radial movement of each of said working members comprising a plate supported by said flanges. the flanges being slotted to engage the plate, the plate being laterally movable within said slots to 1111- cover the working members and permit" their radial withdrawal for disassembling, and a cross-head associated with said workingmembersadapted for movement parallel with the plane of the reaction member.

38. In a hydraulic machine, two opposed parallel flanges, radial working members located betweensaid flanges, a rigid reaction member preventing radial movementof each of said working members comprising a plate supported by said flanges, the flanges being slotted to engage the plate, the plate being laterally movable within said slots to uncover the working members and permit their radial withdrawal for disassembling,

' a cross-head associated with said Working members adapted for movement parallel; with the plane of the reaction member, and

a rolling bearing between the reactionpnem: her and the cross-head.

39. Ina hydraulic mac parallel flanges, radial working members locatedbetween said flanges, a rigid reaction member preventing'radial.movement of each of said working members comprising a plate I with the plane of the reaction member, and

a support-for the'cross-head in opposition to the reaction member.

40. In a hydraulic machine, two opposedparallel flanges, radial working members.

located between said flanges a rigid .reacs hine, two opposed tion member preventing radial movement of each of said working members comprising a plate supported by said flanges, the flanges being slotted to engage'the plate,'tl1e plate being laterally movable within said slots to uncover the working members and permit their radial withdrawal for disasscmbling,a cross-head associated with said working members adapted for movement parallel with the plane of the'reaction memher, a rolling bearing between the reaction. member and the cross-head. and a support for the cross-head in opposition to the reaction member.

41. In a hydraulic machine, two opposed parallel flanges, radial working members located between said flanges, a rigid reaction member preventing radial movement of each of said working members comprising a plate supported by said flanges, the flanges being slotted to engage the plate, the plate being laterally movable within said slots to uncover the wdrking members and permit their radial withdrawal for disassembling, a cross-head associated with said working members adapted for movement parallel ,with the plane of the reaction member, and

a two-part support for the cross-head in op-. position to the reaction member.

42. In a hydraulic machine, two opposed parallel flanges, radial working 'members located between said flanges, a rigid reaction member preventing radial movement of each of said working members comprising a plate supported by said flanges, the flanges being slotted to engage the plate, the plate lltl being laterally movable within said slots to uncover the working members and permit their radial withdrawal for disassembling, a cross-head associated with said working members "adapted for -movement parallel with the plane of the reaction member, a rollingfbearing between the reaction memport for the cross-head in opposition to the reaction member.

43. In a hydraulicmachine, two opposed parallel flanges, radial working members located between said flanges. a rigid reaction member preventing radial movement of each of said working members comprisil'ige a plate" supported by said flanges, the flanges being slotted to engage the plate, the plate being laterally'movable within,sa'id .slots to uncover the working members and permit, their radial withdrawal for disassembling, a cross-head associated with said-working members adapted for movement parallelber and the cross-head, and a two-part sup- IlU with-the plane of the reaction member, and

a support for the cross-head in opposition been removed.

to the reaetionmember. the ,cworkin'g mem-.

let. In a hydraulic machine, two opposed parallel flanges, radial working members and the cross-head, and a support for the cross-head in opposition to the reaction member. the working member being longitudinally movable for withdrawal through the space between the two parts of the support when the reaction plate has been removed. I

45. In a hydraulic machine the combination of two rotating members. one of said members having a series of tangential reac tion faces. a set of piston and cylinder assemblies between each of said reaction faces and the other of said members. and a crosshead connecting the piston and cylinder assemblies of each set.

46. In a hydraulic machine the combination of two rotary members. one of said members having a series of tangential reaction faces. a, plurality of radially dis) sed piston and cylinder assemblies between said members, comprising a set of substantially parallel piston and cylinder assemblies opposite each of said faces. and a crosshead associated with each of said faces and connecting the piston andcylinder assemblies of a set.

47. In a hydraulic machine the combination of a pintle having a fluid passage therein, a member thereon, a second member surrounding said first named member, a plurality of piston and cylinder assemblies between said members for communication with said passage, said assemblies being arranged in parallel sets, and separate means for connectingtherpiston and cylinder assemblies of each set. 1

48. In a hydraulic machineithe combination of a intle having fluid passages therein, a member thereon,a second member surrounding said first named member, a plurality of piston and cylinder assemblies be.- tween said members for communication with said passages, said assemblies being arranged in parallel pairs, and connections between the assemblies of each pair.

49. In a hydraulic machine, a cylinde barrel, cylinders. arranged in pairs therein, and a common communication port; at the inner end of each pair of cylinders.

501111.}; hydraulic machine, a cylinder barrel, cylinders arranged in pairs therein,

associated with said working i for movement. paralleland a common communication port at the inner .end of the cylinders, the cylinders themselves being joined toward the lower end as they approach said port.

51. In a hy raulic machine, a cylinder barrel. cylinders arranged in pairs therein, and

a common communication port at the inner end of the cylinders, the cylinder walls being cut away between the cylinders of each pair toward the 'port.

ln a hydraulic machine, a cylinder barrel, cylinders arranged in pairs therein, and a common communication port at the inner end of the cylinders, t he cylinder walls bemg cut away 'between the cylinders of each pair toward the port, the wall of the port a and the opposed cut-away wall of the cylinder on the same side of the port conforming to an imaginary cylinder inclined to the working cylinder and when extended lying out of contact with the upper, edge of the working cylinder. 5

53. In a hydraulic machine, ,/a cylinder barrel. a pintle upon which it rotates, cylin- (lcrs in the barrel arranged in pairs, a. common port. for eachpair of cylinders, and a port in the pintle adapted to register with the common cylinder port. Y

54. In a hydraulic machine, a cylinder barrel, a pintle upon which it rotates, cylinders in the barrel arranged in pairs, a common port for each pan"- of cylinders, and a port in the pintle adapted to register with the common cylinder port, the wall of the cylinders cutaway between the pairs. In a hydraulic machine, a cylinder barrehapintle upon which it rotates, cylin ders in the barrel arranged in airs, a com- 111011' PQI't for-each pair of cylinders, and a port in the pintle adapted to register with the common cylinder port, the wall of the cylinders cut away between the pairs, the v wall ofeach cylinder being cut away in opposition to the cut-away portion of the common wall. I

inders in the barrel arranged in pairs,- ii common port for each pair of cylinders, and

a port in the pintle adapted to register with the common cylinder ort, each cylinder having an inclined passage leading tothe common port.

T57-I LJI-laydraulic machine, a cylinder hart-clarifi d riving head, a two-part cradle for .flie"' "ving head. 58. In a hydraulic' maching' ancylinder V 7 1m 56. In a hydraulic machine, a cylinder barrel, a pintle upon which it. rotates, cylbarrel and a driving head, a two-partcradle.

for the driving head, said cradle monn s t- 5,:

:for the driving head, and supporting bear ing-s for the driving head located one in each part. v

60. In a hydraulic machine, a cylinder barrel and a driving head, a two-part cradle for the driving head, said cradle mounted folrotation about an axis and removed front the axis of rotation with the driving'head, and a :up'porting bearing for the driving head located one in each part.

61. In a hydraulic machine, two rotating parts, a pintle upon which one is moimted for rotation, a swinging arm upon which the other is mounted for rotation, and means for adjusting the l'iosition \of the swinging member with respect to the pintle to change the displacement of the machine. said swingingvmember comprising acradle surrounding the two rotating parts, there being antifrietion bearings between the swinging member and one of the rotating parts on both sides thereof.

6%.. In a hydraulic machine, a driving head comprising two parallel flange members. a plurality of opposed parallel tangent-ial grooves therein, and individually removable thrust plates located in said grooves.

(53.111 a hydraulic machine. a driving head comprising two parallel flange members, a plurality of opposed parallel tan gential grooves therein, individually removable thrust plates located insaid grooves, and lu s joining said members.

a 64. n a hyd'aulic machine, a driving ,head comprising two parallel flange members, a plurality of opposed parallel tangential grooves therein, individually removable thrust )lates located'in said grooves, and lugs joming said members, said lugs bcing located inside the flangesu v 65. In a hydraulic machine, a driving head comprising two parallel flange members, a plurality of opposed parallel tangential grooves therein, individually removable thrust plates located in said rooves, and lugs joining said members said lugs having bearing surfaces in opposition to bearing surfaces on the thrust plates.

-66. In a hydraulic machine, a driving head comprising two parallel flange members. a plurality of opposed parallel tangential grooves therein, an individually removable thrust plate located in said grooves, lugs joiningsa-id members said lugs having bearing surfaces in opposition to bearing surfaces on the thrust plates, and a crosshead guided between said bearing surfaces.

67.111 a hydraulic machine. a driving head comprising two parallel flange memhers, apluralityof opposed parallel tangential grooves therein, a thrust-plate located insaid grooves, lugs joining said mem- "ber .saidf lugs having-hearing surfaces in opposition to bearing surfaces on the thrust plates, at cross-head guided between said bearing surfaces, and a rolling bearing between the cross-head andthe bearing on the cross-head extending inwardly therefrom be tween said lugs.

69. In a. hydraulic machine. a driving head comprisingtwo parallel flange'members, a plurality ofopposed parallel. tangential grooves therein. a thrust plate located in said grooves, lugs joining said members said lugs having bearing surfaces in opposit ion to bearing surfaces on the thrust plates, :1 cross-head guided between said bearing surfaces. a rolling bearing between the cross-hem! and the bearing on the thrust plate. and a plunger associated with each cross-head extending inwardly therefrom between said lugs. I

70. In a hydraulic machine, a double flange driving member, a group, of radially arranged cylinders between the flanges, a large diameter anti-friction bearing supporting one ofthe flanges on one side of the cylinders, and smaller anti-friction bearings sl'lpporting the other flange on the other side of the cylinders. i

'71. In a hyd aulic machine, two spaced parallel flanges, a radial series ofpiston and "cylinder assemblies having crossheads reciprocable between said flanges, and rigid bars connecting said flanges and underlying said crossheads to retain them in working position.

72. In a hydraulic machine, two parallel.

flanges, a radially arranged group of cylinders between them, rigid connecting bars extending across between the flanges and overlyin the cylinders, the opposedsides of the anges bein slotted, and reaction plates carried in said slots and removable lengthwise thereof, the slots being substantially perpendicular to the axial lines of the engaged in and. supported by said grooves longitudinally movable in said slots for reaction plate and a plunger projecting, theremoval, and means for holding the plate against longitudinal movement.

76. In a hydraulic machine a driving head comprising two parallel flanges and means I for rigidly connecting them, their opposed faces being slotted, a re-action,plate supported within said slots, the plate being longitudinally movable in said slots for removal, and means for holding the plate against longitudinal movement, a plunger and plunger operating means associated with said re-action plate.

7 7. In a hydraulic machine a driving head comprising two parallel flanges and means for rigidly connecting them,their opposed faces being slotted, a re-action plate supported within said slots, the plate being longitudinally movable in said slots for removal, and means for holding the plate against longitudinal movement, a. plunger and plunger operating means associated with said re-action plate, said means comprising a cross head parallel with the refrom. Y Y t r 78. In a hydraulic machine a driving head comprising two parallel flanges and means for rigidly connecting them, their opposed faces being slotted, a re-action plate supported within said slots, the plate being longitudinally movable in said slots for removal, and meansfor holding the plateagainst longitudinal movement, a plunger and plunger operating means associated with said re-action plate, said means comprising a cross head parallel with the re-action plate and a plunger projecting therefrom, means for holding the cross head to a path parallel to the re-action plate.

79. In a hydraulic machine a driving head comprising two parallel flanges and means for rigidly connecting them, their opposed. faces being slotted, a re-action plate supported within said slots, the plate being longitudinally movable in said slots for re- 'moval," and means for holding the plate against longitudinal movement, a plunger and plunger operating means associated with! said .re-action plate, said means comprising a cross head. parallel with the re-action plate and a plunger projecting therefrom, means for holding the cross head to a path parallel v toth'e re-action plate, said means comprising anti-friction bearings between the cross headand the 're-action' plate and supporting *means" adapted-to hold the cross head -in workingrelation with the anti-friction bearin s. w

80. n a hydraulic machine a driving head comprising two parallel flanges, means for rigidly connecting them comprising cross bars extending between them, the opposed faces of the flanges being slotted, individually removable re-action plates located within said slots, the cross bars having bearing surfaces opposed to the working "surfaces of the re-action plates.

81. In a hydraulic machine a driving head comprising two parallel flanges, means for rigidly connecting them comprising cross bars extending between them, the opposed faces of the flanges bein slotted, re-action plates located within sa1d slots, the cross bars having bearing surfaces opposed to the working surfaces of the reaction plates, across head adapted for longitudinal movement between the bearing surfaces on the cross bars and the re-action plates.

82. In a hydraulic machine a driving head comprising two parallel flanges, means for rigidly connecting them comprising cross bars extending between them, the'opposed faces of the flanges being slotted, re-action plates located within said slots, the cross bars having bearing surfaces opposed to the working surfaces of the re-action plates, a cross head adapted for longitudinal movement between the bearing surfaces on the 'cross bars and the re-action plates, and an anti-friction bearing between the cross head and the re-action plate.

83. In a hydraulic machine a tapered pintle, a cylinder barrel rotatable thereon, radial plungers mounted for reciprocation in the barrel, a driving head and driving connections between it and the plungers, and means for axially adjusting the position of the driving head to position the barrel on the pintle.

84. In a hydraulic machine a tapered pintle, a cylinder barrel rotatable thereon, radial plungers mounted for reciprocation in the cylinder barrel, and means engaging said plungers, adapted tofexert lateral pressure thereon, to axially position the cylinder barrel. p

85. In a hydraulicmachine a tapered pintle, a' cylinder barrel rotatable thereon, radial plungers mounted for reciprocation in the plungers, adapted to exert lateral pressure thereon, to axially position the cylinder cylinder barrel, and means engaging said barrel said means comprising adriving head, I

means for rotating it and adriving connection between itand the plungers.

86., In a hydraulic machine, a tapered pintle, a cylinder .barrel rotatable thereon, radial plungers mounted for reciprocation in the barrel, a driving-head associated with said plungers, and a driving connection between the driving head and the plungers, said connection being arranged to axially displace the plungers as the driving head is rotated and to exert a lateral pressure on the plungers independent of rotation to axially adjust the osition of the cylinder barrel.

87 In a h tle, a cylinder barrel rotatable thereon, radial plungers mounted for reciprocation in the cylinderbarrel and a driving head adapted to operate them, means interposed between the driving head and the cylinder barrel for axially positioning the cylinder barrel.

88. In a hydraulic machine, two parallel rows of working members, a single crosshead associated with each pair of working members, a reaction plate in line with said cross-head, rolling bearings interposed be-' tween the reaction plate and the cross-head, a cage inclosing said bearing members and holding them in position, and means associated with said cage and engaging the crosshead and reaction plate between the rows of working members for positioning the cage, said means comprising a gear and rack teeth on cross-head and reaction member i ciated with said cage and engaging the cross-head and reaction plate between the rows of workingmembers for positioning the cage, saidmeans comprising a gear and rack teeth on cross-head and reaction member in mesh with said gear, the reaction member being mounted for lateral withdrawal, the working member and cross-head being mounted for withdrawal at right anglesto the reaction member.

90. In a hydraulic machine, a cylinder. barrel, cylinders therein, a driving head, plungers mounted "for reciprocation in said cylinders, cross-heads,gui ded for reciprocation in said head, push pins rigidly mounted on said crossheads and loosely engaging said plungers, and loose pin connectionsbetween 7 said push pins and plungers.

'91. 'In a hydraulic machine, a cross-head and a reaction plate,- an anti-friction bearing between them, a gear associated with such bearing out of linewith the bearing -mem her, and teeth in the opposed faces of the cross-head and reaction member in mesh with'said gear,'sa-i d teeth extending clear to theend ofcross-head and reaction member- 'on opposed ends and terminating short of the end of saidmembers onjthe other end.

and a reaction plate, ananti-friction bearydraulic machine a tapered pin ing between them, a gear associated with such bearing out of line with the bearing member, and teeth in the opposed faces of the cross-head-and reaction member in mesh with said gear,'said teeth extending clear to the end of cross-head and reaction .member on opposed ends and terminating short of the end of said members on the other end whereby lateral separation of the crosshead and reaction member causes the gear t roll from between said members.

93. In a hydraulic transmission, a hydraulic machine adapted for variable displacement, means for varying said displacement, a control member and 'a working connection between it and the displacement varying means, and yielding means in said connection adapted to prevent any backlash be tween the control member and the displacement varying means.

i 94. In a variable delivery pump, a strokechanging member, an operating member, a .rigid link connection between them, and a yielding member to maintain a non-reversing' stress upon the rigidconnection.

95. In a hydraulic machine the combina- 1 tion of a plurality of piston and cylinder assemblies, a fluid actuated member for regulating the efiective strokes of said piston and cylinder assemblies, fluid passages in said member, and a fluid distributing valve -movable in said member and cooperating with said passages to control said member.

96. In a hydraulic machine the combination of a plurality of piston and cylinder assemblies, means including a-fluid actuated plunger having fluid'passages, and an element movable lengthwise of. said plunger and cooperating with said passages for controlling said plunger.

97. .In a variable displacement pump or motor displacement regulating means comprising a fluid actuated plunger having fluid passages, and an'element cooperating with said passages for controlling said plunger, said element being movable parallelto the direction of movement of said plunger todetermine the extent of move ment t ereof.

motor the combination of a cylinder, a

plunger movable therein to regulate displacement, fluid passages in said plunger,

a. fluidpressure source, a. fluid distributing valve movable 1n said plunger for controlhng said passages, and fluid connections between said valve and said fluid pressure source. 99. In a variable displacement pump or y ,motor the combination of displacement 92. In a hydraulic machine, a cross-head regulatin' mechanism, an auxiliary pump, for supp ying an operating fluid to' said mechanism, and a fluid distributing valve in open communication with said auxiliary pump for controlling the application of fiuid therefrom to said regulating mechanism.

. 100. The combination with a variable dis placement pump or motor, of an' auxiliary pump, displacement.regulating mechanism actuated solely by fluid delivered from said auxiliary-pump, and means for controlling communication between said mechanism" and said auxiliary pump to control said mechanism.

101. The-combinationwith a variable dis- "placement pump vor motor of a hydraulic circuit connected therewith, means including an auxiliary pump for supplying liquid to said circuit to replenish leakage therefrom,

displacement regulatin mechanism actuplacement. pump or motor of ,an auxiliary pump, displacement regulating means including a plunger actuated by fluid delivered by said auxiliary pump, and a fluid disjtributing valve connected with said pump and movable lengthwise of said plunger for controlling said plunger.

Signed at Chicago, county of Cook and State of Illinois, this 28th day of June, 1921.

' WALT R m nus. 

